Semiconductor device including high-K metal gate having reduced threshold voltage variation

ABSTRACT

A semiconductor device having a reduced variation in threshold voltage includes a semiconductor substrate with a high dielectric-constant (high-k) layer deposited in a gate trench and on a semiconductor portion of the substrate. At least one workfunction layer has an arrangement of first and second workfunction granular portions on an upper surface of the high-k layer to define a workfunction of the semiconductor device. The arrangement of first and second workfunction granular portions define a granularity of the at least one workfunction layer. A gate contact material fills the gate trench, wherein the high-k layer has a concentration of oxygen vacancies based on the granularity of the at least one work function metal layer so as to reduce the variation in the threshold voltage.

BACKGROUND

The present invention relates to semiconductor devices, and moreparticularly, to complementary metal-oxide-semiconductor (CMOS) devicesincluding high-k metal gate structures.

Field effect transistors (FETs) are widely used in the electronicsindustry for switching, amplification, filtering, and other tasksrelated to both analog and digital electrical signals. Most common amongthese are metal-oxide-semiconductor field-effect transistors (MOSFET orMOS), in which a gate structure is energized to create an electric fieldin an underlying channel region of a semiconductor body, by whichelectrons are allowed to travel through the channel between a sourceregion and a drain region of the semiconductor body. Complementary MOS(CMOS) devices have become widely used in the semiconductor industry,wherein both n-type and p-type (NMOS and PMOS) transistors are used tofabricate logic and other circuitry.

As the scaling of CMOS devices continues to decrease, variability inthreshold voltage (Vt) of the device becomes more prevalent. Forinstance, CMOS devices typically implement high-k metal gate structuresthat include one or more work function metal layers. The work functionmetal layers have a natural granularity typically referred to as metalgrain granularity (MGG). The orientation of the each grain, however,affects the work function of the metal layers thereby causing variationsin the overall Vt of the device. In addition, the high-k materialforming the gate dielectric layer can include a distribution ofpositively charged oxygen vacancies which contribute to randomvariations in the Vt of the device.

SUMMARY

According to a non-limiting embodiment, a method of fabricating asemiconductor device comprises forming at least one gate trench in asemiconductor substrate. The gate trench exposes a semiconductor portionof the substrate. The method includes forming a high dielectric-constant(high-k) layer in the at least one gate trench and on the semiconductorportion. The method further includes forming at least one workfunctionlayer having an arrangement of first and second workfunction granularportions on an upper surface of the high-k layer to define aworkfunction of the semiconductor device. The arrangement of first andsecond workfunction granular portions define a granularity of the atleast one workfunction layer. The method further includes performing athermal anneal process so as to control a concentration of oxygenvacancies in the high-k layer based on the granularity of the at leastone work function metal layer thereby reducing a variation in thethreshold voltage.

According to another non-limiting embodiment, a method of forming asemiconductor device having reduced variations in threshold voltagecomprises forming first and second gate trenches in a semiconductorsubstrate. The first and second gate trenches expose first and secondportions of the semiconductor substrate, respectively. The methodfurther includes forming a first high dielectric-constant (high-k) layerin the first gate trench and on the first semiconductor portion, andforming a second high-k layer in the second gate trench and on thesecond semiconductor portion. The method further includes depositing afirst number of workfunction layers atop the first high-k layer in thefirst gate trench and a different second number of workfunction layersatop the second high-k layer in the second gate trench. The first numberof workfunction layers defines a first threshold voltage and the secondnumber of workfunction layers defines a second threshold voltage. Eachof the work function layers has workfunction granular portions thatdefine a respective granularity. The method further comprises performinga thermal anneal process that controls a concentration of oxygenvacancies in the high-k layer based on the granularity of the at leastone work function metal layer so as to reduce variations in the firstand second threshold voltages.

According to still another non-limiting embodiment, a semiconductordevice having a reduced variation in threshold voltage includes asemiconductor substrate with a high dielectric-constant (high-k) layerdeposited in a gate trench and on a semiconductor portion of thesubstrate. At least one workfunction layer has an arrangement of firstand second workfunction granular portions on an upper surface of thehigh-k layer to define a workfunction of the semiconductor device. Thearrangement of first and second workfunction granular portions define agranularity of the at least one workfunction layer. A gate contactmaterial fills the gate trench, wherein the high-k layer has aconcentration of oxygen vacancies based on the granularity of the atleast one work function metal layer so as to reduce the variation in thethreshold voltage.

Additional features are realized through the techniques of the presentinvention. Other embodiments are described in detail herein and areconsidered a part of the claimed invention. For a better understandingof the invention with the features, refer to the description and to thedrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an intermediate semiconductor device followingremoval of a dummy gate stack to form a gate trench in an activesemiconductor layer of a semiconductor substrate according to anon-limiting embodiment of the invention;

FIG. 2 illustrates the semiconductor device of FIG. 1 followingdeposition of a high-k layer on an upper surface of the activesemiconductor layer, sidewalls of the gate trench, and on an uppersurface of a gate dielectric layer exposed by the gate trench;

FIG. 3 illustrates the semiconductor device of FIG. 2 followingdeposition of an intermediate workfunction metal layer on an uppersurface of the high-k layer;

FIG. 4A illustrates the semiconductor device of FIG. 3 followingdeposition of an upper workfunction metal layer on an upper surface ofthe intermediate workfunction metal layer;

FIG. 4B illustrates the semiconductor device of FIG. 3 followingdeposition of an upper workfunction metal layer directly on an uppersurface of the high-k layer according to another non-limitingembodiment;

FIG. 5 illustrates the semiconductor device of FIG. 4A followingdeposition of a bulk contact layer on an upper surface of the upperworkfunction layer so as to fill the gate trench;

FIG. 6A illustrates the semiconductor device of FIG. 5 after planarizingthe bulk contact layer to form a gate contact;

FIG. 6B illustrates the semiconductor device of the second embodimentshown in FIG. 4B to from a gate contact;

FIG. 7 illustrates the semiconductor device of FIG. 6A undergoing athermal anneal process; and

FIG. 8 illustrates the controlled formation of oxygen vacancies in thehigh-k layer following the thermal anneal process of FIG. 7 according toa non-limiting embodiment.

FIG. 9 is a flow diagram illustrating a method of fabricating asemiconductor device having a reduced variation in threshold voltageaccording to a non-limiting embodiment.

DETAILED DESCRIPTION

The continued desire to reduce the scaling of field effect transistorshave led to trends to decrease the thickness of the gate dielectriclayer in high-k metal stack devices. Thin high-k dielectrics, such asthose based on hafnium or zirconium for example, can be used to reducegate leakage current compared to SiON gate dielectrics with comparablegate stack capacitance. However, depositing a high-k dielectric materialon a silicon-based channel can result in a threshold voltage (Vt) thatis higher than desired for certain applications. For instance, ap-channel FET (pFET) having a hafnium- or zirconium-based high-k gatedielectric on a silicon-based channel can have a Vt that is 0.5 volts(V)-−0.6 V higher than desired.

A factor contributing to this higher Vt is the formation of oxygenvacancies (Vo) in a high-k dielectric in the presence of a gateelectrode with a sufficiently high workfunction, particularly duringdopant activation anneal. As an example, the volume density of Vo inHfO₂ or HfSiON, for example, is small (although not zero) because therequired energy input for Vo formation in the HfO₂ or HfSiON in contactwith an ultra-high vacuum environment is large. However, when HfO₂ orHfSiON is near a silicon channel and a gate electrode with asufficiently high workfunction, two processes reduce (and may even makenegative) the required energy input for Vo formation. The first isoxygen transfer from the HfO₂ or HfSiON to the Si substrate, oxidizingthe substrate. This can occur even when a SiO₂ interfacial layer ispresent between the HfO₂ or HfSiON layer and the Si substrate. Thesecond is subsequent electron transfer from the HfO₂ or HfSiON to thegate electrode. As a consequence of these processes, more oxygenvacancies are formed in the HfO₂ or HfSiON than would otherwise exist.These oxygen vacancies can be dual-positively charged so that thedielectric has a net positive charge, thereby shifting devicecharacteristics. Consequently, the threshold voltage (Vt) and theflatband voltage (Vfb) can be shifted towards more negative values.

Various embodiments of the invention provide a semiconductor deviceincluding a high-k metal gate having a reduced threshold voltagevariation. Unlike conventional semiconductor devices, which aresusceptible to threshold voltage variations caused by the metal graingranularity (MGG) of the workfunction metal layers and randomdistribution of positively charged oxygen vacancies within theworkfunction metal layer, at least one embodiment provides asemiconductor device having a controlled distribution of oxygenvacancies within the metal gate layers that essentially cancels ornegates the threshold voltage variation typically caused by the MGG ofthe workfunction metal layers. As a result, the semiconductor deviceaccording to various non-limiting embodiments of the invention hasreduced threshold voltage variations compared to conventionalsemiconductor devices implementing high-k metal gate stacks.

With reference now to FIG. 1, an intermediate semiconductor device 100is illustrated following removal of a dummy gate stack (not shown). Inthe present specification and claims, an “intermediate” semiconductormay be viewed as a semiconductor device in a stage of fabrication priorto a final stage. The removal of the dummy gate stack creates a gatetrench 102 that exposes an interfacial layer 104 disposed on an uppersurface of an active semiconductor layer 106. According to anon-limiting embodiment, the active semiconductor layer 106 constitutesa portion of a bulk semiconductor substrate. It should be appreciated,however, that the active semiconductor layer 106 may be disposed atop aburied insulator layer (not shown) to form a semiconductor-on-insulator(SOI) substrate as understood by one of ordinary skill in the art. Theactive semiconductor layer 106 may be formed from various semiconductormaterials including, but not limited to, silicon (Si).

The semiconductor device 100 further includes a pair of opposing gatespacers 108 formed atop the active semiconductor layer 106. The gatespacers 108 may be formed from various dielectric materials including,but not limited to, silicon nitride (SiN). The interfacial layer 104 isformed atop a portion of the active semiconductor layer 106 locatedbetween the spacers 108, and serves to improve the interface between theupper surface of the actively semiconductor layer 106 and a gateinsulation layers (discussed in greater detail below) typically formedfrom a high dielectric (i.e., high-k) material. The interfacial layer104 is formed from various materials including, but not limited to, anozonated oxide material, a thermal oxide material, a chemical oxidematerial, or an ultraviolet ozone (UVO) oxidized. For example, theinterfacial layer 104 is formed of SiO₂. The thickness (i.e., verticalheight) of the interfacial layer 104 can range, for example, fromapproximately 0.5 nm to approximately 1.5 nm for logic devices and fromapproximately 2.0 nm to approximately 3.0 nm for low leakage devices,such as I/O devices.

As further illustrated in FIG. 1, the semiconductor device 100 includesraised source/drain regions 110 and an interlayer dielectric (ILD)material 111. The raised source/drain regions 110 are formed on an uppersurface of the active semiconductor layer 106. According to anon-limiting embodiment, the raised source/drain regions 110 can beformed by performing an epitaxy process to grow a semiconductor materialsuch as Si, for example, from an upper surface of the activesemiconductor layer 106. The epitaxially grown semiconductor materialmay be in-situ doped with various dopants including, but not limited to,boron or arsenic, to increase the conductivity of the raisedsource/drain regions 110.

The ILD material 111 is formed on an upper surface of the activesemiconductor layer 106. According to a non-limiting embodiment, the ILDmaterial comprises silicon dioxide (SiO₂), for example, and may beformed according to various deposition techniques including, but notlimited to, chemical vapor deposition (CVD).

Turning now to FIG. 2, a high-k layer 112 is formed on the substrate101, and conforms to the side walls of the gate trench 102 and the uppersurface of the interfacial layer 104. According to a non-limitingembodiment, the high-k layer 112 is formed of various high-k materialsincluding, but not limited to, hafnium dioxide (HfO₂), hafnium silicondioxide (HfSiO₄), zirconium oxide (ZrO₂), and zirconium silicon dioxide(ZrSiO₄). The high-k layer 112 is deposited using various depositiontechniques such as, for example, an atomic layer deposition (ALD)process, or chemical vapor deposition (CVD).

Referring to FIG. 3, a first layer 114 is formed on an upper surface ofthe high-k layer 112. The first layer 114 may be deposited using varioustechniques including, but not limited to, ALD or CVD, and may be formedfrom various materials including, but not limited to, an aluminum-freemetal nitride layer. For example, the first layer 114 may include analuminum-free metal nitride material selected from a group comprisingtitanium nitride (TiN) and tantalum nitride (TaN). The thickness of thefirst layer 114 can be adjusted to define a work function characteristicof the device 100. According to a non-limiting embodiment, the firstlayer 114 has a thickness ranging from approximately 10 angstroms (Å) toapproximately 30 Å.

Turning now to FIG. 4A, the semiconductor device of FIG. 3 isillustrated following deposition of an upper workfunction metal layer116 on an upper surface of the intermediate workfunction metal layer114. In this manner, a p-type semiconductor device (i.e., a pFET) may beformed. The second layer 116 may be deposited using an ALD process, forexample, and includes various metal ceramic materials. For example, thesecond layer 116 may be an aluminum-containing metal material selectedfrom the group comprising titanium-aluminum (TiAl),titanium-aluminum-nitrogen (TiAlN), and titanium-aluminum-carbon(TiAlC). According to a non-limiting embodiment, the second layer 116may be formed by applying layers of Al and one or more additional metalsin sequential atomic layers in an ALD process. In an embodiment in whichthe second layer 116 comprises TiAl, layers of Ti and Al may bedeposited in sequence in predetermined ratios.

In the embodiment in which the second layer 116 includes TiAl, the ratioof Al:(Al+Ti) may be adjusted to adjust a work function of the device100. The thickness of the second layer 116 can range, for example, fromapproximately 10 Å to approximately 60 Å. According to a non-limitingembodiment, a ratio of Al:(Al+Ti) is substantially constant throughoutthe entire second layer 116. In other words, layers of Al and Ti aredeposited by an ALD process in constant ratios. According to anon-limiting embodiment, the percentage of Al relative to Al+Ti in thesecond layer 116 ranges, for example, from approximately 10% toapproximately 90%.

According to another embodiment, the second layer 116 is formed bydepositing layers of titanium nitride (TiN) and titanium aluminumnitride (TiAlN) in a particular sequence to obtain a layer of TiAlN. Inthis manner, the second layer 116 can be formed with ratio of Al:Ti, ora predetermined gradient of ratios of Al:Ti.

With reference to FIG. 4B, the semiconductor device of FIG. 3 isillustrated following deposition of an upper workfunction metal layer116 atop the high-k layer 112 according to another non-limitingembodiment. Unlike the embodiment of FIG. 4A, the device 100 excludesthe intermediate workfunction metal layer 114. In this manner, the upperworkfunction metal layer 116 is formed directly on an upper surface ofthe high-k layer 112 so as to form an n-type semiconductor device 100′(i.e., nFET). The upper workfunction metal layer 116 can be depositedusing the various aforementioned deposition processes to achieve thesame upper workfunction metal layer characteristics and propertiesdiscussed above.

Although the nFET device 100′ illustrated in FIG. 4B is shown separateand isolated from the pFET device illustrated in FIG. 4A, it should beappreciated that the nFET device 100′ and pFET device can be located ona common substrate. For instance, a conformal intermediate workfunctionmetal layer 114 can be deposited atop the high-k layer 112 included withboth the pFET device 100 and the nFET device 100′. Thereafter, a masklayer (not shown) can be deposited atop the intermediate workfunctionmetal layer 114 and subsequently patterned. Patterning the mask layerallows for exposing a portion of the intermediate workfunction metallayer 114 included with the nFET device 100′ while the remaining portionof the intermediate workfunction metal layer 114 included with the pFETdevice 100 remains covered. The exposed intermediate workfunction metallayer 114 can then be selectively etched (i.e., removed), and the upperworkfunction metal layer 116 can be deposited directly on an uppersurface of the high-k layer 112 to form the nFET device 100′ shown inFIG. 4B. After forming the nFET device 100′, the mask layer can beremoved from the pFET device and the process flow can be continued asdiscussed further below.

In addition it should be appreciated that when forming the pFET device100 and the nFET device 100′ together on a common substrate, differentcombination of masking techniques may be implemented in order to achievethe combination of workfunction metal layers 114-116 for each device100-100′. The workfunction metal layers 114-116 may define the thresholdvoltage (Vt) for a particular semiconductor device. For example, insteadof depositing a single conformal intermediate workfunction layer 114 onthe upper surface of the high-k layer 112 included with both the pFETdevice and nFET device, a first masking layer (not shown) can bedeposited on the upper surface of the high-k layer 112 included withboth the pFET device 100 and nFET device 100′. The first masking layercan then be patterned to expose the high-k layer 112 of the pFET device100 and the upper workfunction metal layer 116 can then be deposited onthe upper surface of the first masking layer and the upper surface ofthe exposed high-k layer 112. Thereafter, a second masking layer (notshown) can be deposited and patterned so as to expose the upperworkfunction metal layer 116 of the nFET device 100′, while covering theupper workfunction metal layer 116 included with the pFET device 100. Anetching process selective to the material of the upper workfunctionmetal layer 116 is subsequently performed so as to re-expose the firstmasking layer included with the nFET device 100′. Finally, the first andsecond masking layers are selectively removed so as to provide the pFETdevice 100 shown in FIG. 4A and the nFET device 100′ shown in FIG. 4B.

Referring now to FIG. 5, the semiconductor device of FIG. 4A isillustrated after forming a bulk contact layer 118 atop the upperworkfunction metal layer 116. The bulk contact layer 118 is deposited onan upper surface of the upper workfunction layer 116 so as to completelyfill the gate trench (previously indicated as element 102). In thismanner, the upper workfunction metal layer 116 is interposed between thebulk contact layer 118 and the intermediate workfunction metal layer114.

The bulk contact layer 118 may be formed of any conductive metalincluding, but not limited to, aluminum and tungsten. The bulk contactlayer 118 may be formed in a conforming process, such as ALD, or anon-conforming process, such as PVD. Subsequently, a planarizationprocess is applied to the pFET device 100. The planarization processincludes a chemical-mechanical planarization (CMP) process, for example,which stops on the upper surface of the upper workfunction metal layer116 as illustrated in FIG. 6A. Accordingly, the upper workfunction metallayer 116 is interposed between the gate contact 120 and theintermediate workfunction metal layer 114.

In this manner, a gate contact 120 is formed in the gate trench and isflush with the upper surface of the workfunction metal layer 116 asfurther illustrated in FIG. 6A. In a similar manner, a CMP process canbe applied to the nFET device 100′ as illustrated in FIG. 6B. Unlike thepFET device 100, however, the upper workfunction metal layer 116 isinterposed between the gate contact 120 and the high-k layer 112.

Turning now to FIG. 7, the pFET device 100 is illustrated undergoing athermal anneal process. The thermal anneal process includes exposing thepFET device 100 to low temperatures of less than or equal to 450 C inthe presence of a reducing ambient, e.g., hydrogen (H₂) forapproximately 30 min. In response to the thermal anneal process, metalworkfunction oxygen vacancies (Vo) are created in the high-k layer 112.Unlike conventional high-k metal gate semiconductor device, however,non-uniform groupings of oxygen vacancies (not shown in FIG. 7) arecreated in the high-k layer 112 based on the local metal work functionvariability. That is, a controlled formation of higher amount of oxygenvacancies are created beneath the higher work function portion of themetal electrode so as to cancel out variations in threshold voltagestypically caused by the natural granularity, i.e., the metal graingranularity (MGG), of the intermediate workfunction layer 114 and/or theupper workfunction layer 116.

Turning to FIG. 8, for example, a controlled formation of oxygenvacancies 122 in the high-k layer 112 following the thermal annealprocess of FIG. 7 is illustrated according to a non-limiting embodiment.A close-up view of the pFET device 100 is illustrated, which shows theMGG of the intermediate workfunction layer 114. For example, the MGG ofthe intermediate workfunction layer 114 includes a random arrangement oflow workfunction grain portions 124 a and high workfunction grainportion 124 b. The low workfunction grain portions 124 a may be definedas grains with crystal orientation showing lower workfunction or grainsincluding higher amount of Al if it is an Al-containing alloy, whereasthe high workfunction grain portions 124 b may be defined as grains withcrystal orientation showing higher workfunction or grains includinglower amount of Al if it is an Al-containing alloy. Due to the Fermilevel pinning effect, a greater majority of positively charged oxygenvacancies 122 are concentrated beneath the high workfunction grainportions 124 b compared to the low workfunction grain portions 124 a inresponse to the low heat applied according the thermal anneal process.By concentrating the majority of oxygen vacancies 122 beneath the highworkfunction grain portions 124 b, threshold voltage variationstypically caused by the MGG of the workfunction metal layer 114 aresubstantially reduced or even eliminated. Accordingly, a high-k metalgate semiconductor device implementing workfunction metal layers isprovided having reduced variations in Vt compared to conventionalsemiconductor devices.

Turning now to FIG. 9, a flow diagram illustrates a method offabricating a semiconductor device having a reduced variation inthreshold voltage according to a non-limiting embodiment. The methodbegins at operation 900, and at operation 902 one or more gate trenchesare formed in a semiconductor. In this manner, a portion (e.g., achannel portion) of the semiconductor substrate is exposed. According toa non-limiting embodiment, the gate trench can be formed according to areplacement metal gate (RMG) process. For instance, a dummy gate stackpreviously constructed atop the semiconductor substrate can be removedthereby forming a corresponding gate trench in the substrate. Atoperation 904, a conformal high-k gate layer is formed on an uppersurface of the semiconductor substrate. The high-k layer conforms to thesidewalls of the gate trench and the upper surface of the exposedchannel portion. The high-k layer is formed of various high-k gatedielectric materials including, but not limited to, HfO₂. According to anon-limiting embodiment, an interfacial layer may also be deposited atoperation 904 prior to depositing the high-k gate layer. The interfaciallayer may be formed of SiO₂, for example, and serves to improve theinterface between the upper surface of the channel portion and thesubsequently formed high-k layer.

Turning to operation 906, a first workfunction layer is deposited on anupper surface of the high-k layer. The first work function layerincludes an aluminum-free metal nitride layer comprising analuminum-free metal nitride material selected from the group comprisingtitanium nitride (TiN) and tantalum nitride (TaN). At operation 908, asecond workfunction layer is deposited on an upper surface of the firstworkfunction layer. The second work function layer comprises analuminum-containing metal material selected from the group comprisingtitanium-aluminum (TiAl), titanium-aluminum-nitrogen (TiAlN), andtitanium-aluminum-carbon (TiAlC). At operation 910, a gate contactmaterial is deposited on an upper surface of the second work functionlayer so as to fill the gate trench. The gate contact material includes,for example, Al or W. At operation 912, a planarization process such asa CMP process, for example, is performed which stops on an upper surfaceof the underlying workfunction layer. In this manner, a gate contact isformed having an upper surface that is flush with the workfunction metallayer. At operation 914, a thermal anneal process is performed so as tocontrol the formation of oxygen vacancies in the high-k layer based onthe granularity of one or more of the workfunction layers, and themethod ends at operation 916. According to a non-limiting embodiment,the workfunction layer formed on the high-k layer includes anarrangement of high workfunction granular portions and low workfunctiongranular portions, and the thermal anneal process controls thedistribution of oxygen vacancies such that a first concentration of theoxygen vacancies is formed in the high-k layer beneath the lowworkfunction granular portion and a greater second concentration of theoxygen vacancies are formed in the high-k layer beneath the highworkfunction granular portion. In this manner, the higher concentrationof oxygen vacancies cancels out the threshold voltage variation causedby the high workfunction granular portions of the workfunction layer.With respect to the process flow described above, it should beappreciated that the thermal anneal process may be performed at anystage following deposition of the aluminum-containing workfunctionlayer. In addition, various standard back-end-of-line processes, forexample, may be performed after the method ends at operation 916.

Although the flow diagram described above illustrates a process offorming a pFET device, it should be appreciated that an nFET device maybe formed in a similar manner. For instance, the nFET device may beformed by omitting operation 906 which deposits the aluminum-free metalnitride layer atop the high-k layer. In this manner, a nFET device maybe formed including an aluminum-containing workfunction layer depositeddirectly on an upper surface of the high-k layer. In addition, it shouldbe appreciated that the pFET device and nFET device may be formed on thesame semiconductor substrate. In this case, the process flow includesone or more workfunction masking and patterning processes such that thepFET device includes the aluminum-free workfunction layer formeddirectly on the high-k layer, while nFET device includes thealuminum-containing workfunction layer formed directly on the high-klayer as described in detail above.

As described in detail above, various embodiments of the inventionprovide a semiconductor device including a high-k metal gate having areduced threshold voltage variation. Unlike conventional semiconductordevices, at least one embodiment provides a semiconductor device havinga controlled distribution of oxygen vacancies within the metal gatelayers that essentially cancels or negates the threshold voltagevariation typically caused by the MGG of the workfunction metal layers.In this manner, the semiconductor device according to variousnon-limiting of the invention has reduced threshold voltage variationscompared to conventional semiconductor devices implementing high-k metalgate stacks.

The descriptions of the various embodiments of the present inventionhave been presented for purposes of illustration, but are not intendedto be exhaustive or limited to the embodiments disclosed. Manymodifications and variations will be apparent to those of ordinary skillin the art without departing from the scope and spirit of the describedembodiments. The terminology used herein was chosen to best explain theprinciples of the embodiments, the practical application or technicalimprovement over technologies found in the marketplace, or to enableothers of ordinary skill in the art to understand the embodimentsdisclosed herein.

What is claimed is:
 1. A semiconductor device having a reduced variationin threshold voltage, comprising: a semiconductor substrate including ahigh dielectric-constant (high-k) layer in at least one gate trench andatop a semiconductor portion of the substrate; at least one workfunctionlayer having an arrangement of first and second workfunction granularportions on an upper surface of the high-k layer to define aworkfunction of the semiconductor device, the arrangement of first andsecond workfunction granular portions defining a granularity of the atleast one workfunction layer; and a gate contact material that fills thegate trench, wherein the high-k layer has a concentration of oxygenvacancies based on the granularity of the at least one work functionmetal layer thereby reducing the variation in the threshold voltage. 2.The semiconductor device of claim 1, wherein the granularity is definedby an arrangement of high workfunction granular portions and lowworkfunction granular portion in the at least one workfunction layer. 3.The semiconductor device of claim 2, wherein a first concentration ofthe oxygen vacancies is formed in the high-k layer beneath the lowworkfunction granular portion and a second concentration of the oxygenvacancies are formed in the high-k layer beneath the high workfunctiongranular portion, the second concertation being greater than the firstconcentration.
 4. The semiconductor device of claim 1, wherein the atleast one workfunction layer includes an aluminum-free metal nitridelayer comprising an aluminum-free metal nitride material selected fromthe group comprising titanium nitride (TiN) and tantalum nitride (TaN),and wherein the gate contact material is selected from a groupcomprising aluminum (Al) and tungsten (W).